KR101283244B1 - Network interface apparatus and system for a wireless ethernet - Google Patents

Abstract

In accordance with another aspect of the present invention, a network access device includes a network interface card (NIC) controller for converting a gigabit-class wired Ethernet signal into a PCIe signal, and converting a PCIe signal received from the NIC controller into an analog signal. And an RF transceiver for converting an analog signal input from the radio network processor into an RF signal of a 60 GHz frequency band and transmitting the RF signal to a wireless terminal device.

Description

NETWORK INTERFACE APPARATUS AND SYSTEM FOR A WIRELESS ETHERNET}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network connection device for wireless Ethernet, and more particularly, to a network connection device and a system for converting a gigabit wired Ethernet signal into a wireless Ethernet signal.

In general, Gigabit Ethernet, a standard of the IEEE 802.3 Ethernet group, was initially used in enterprise-class local area networks (LANs), such as schools and businesses, due to distance limitations of up to 5 km. In addition, as Gigabit Ethernet has been developed as an optical transceiver with a maximum distance of 100 km from the company's standard, the use area is being extended to metro area network of metropolitan scale.

Currently, wired Ethernet used in the home can be classified into 10Mbps, 100Mbps, 1000Mbps and 1Gbps, and it is expected that 1Gbps wired Ethernet will be widely used in the future. On the other hand, in order to use a gigabit-class wired Ethernet, a network connection device, that is, a network interface card (hereinafter referred to as "NIC") is required in the desktop.

The network connection device may convert the Ethernet signal coming into the wire into a Peripheral Component Interconnect (PCI) signal or a PCI Express (PCI express, PCIe) signal to provide a central processing unit (CPU).

Meanwhile, desktop access devices for gigabit wired Ethernet have already been produced and provided by several companies. However, there is no network connection device capable of wirelessly connecting a gigabit wired Ethernet that is introduced into the home to a laptop or the like. Therefore, there is an urgent need for a network connection device capable of wirelessly connecting the gigabit-class wired Ethernet signal to a notebook computer.

The present invention provides a network access device and system capable of wirelessly connecting a gigabit wired Ethernet signal introduced into a home from a mobile terminal device.

The present invention also provides a network connection device and a system capable of reproducing video and audio data wirelessly transmitted from a mobile terminal device on a display device.

The present invention provides a network interface card (NIC) controller for converting a gigabit-class wired Ethernet signal into a PCIe signal; A wireless network processing unit for converting the PCIe signal received from the NIC control unit into an analog signal; And an RF transceiver for converting an analog signal input from the wireless network processor into an RF signal of a 60 GHz frequency band and transmitting the RF signal to a wireless terminal device.

According to an embodiment of the present invention, a notebook user may use a high-speed data service by wirelessly accessing a gigabit-class wired Internet introduced into a home. In addition, the notebook user can wirelessly transmit the video and audio data stored in the notebook in real time to play through the TV.

Meanwhile, various other effects will be directly or implicitly disclosed in the detailed description according to the embodiment of the present invention to be described later.

1 is a diagram illustrating a network connection system providing an environment in which a wired Ethernet signal introduced into a home can be wirelessly connected from a notebook computer;
2 is a block diagram of a wireless NIC transceiver according to an embodiment of the present invention;
3 is a block diagram of a wireless NIC terminal according to an embodiment of the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The present invention provides a network connection device and system for converting a gigabit wired Ethernet signal introduced into the home into a wireless Ethernet signal.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 illustrates a network access system that provides an environment in which a wired Ethernet signal entering a home can be wirelessly connected from a notebook.

Referring to FIG. 1, the network access system includes a mobile terminal device 110, a wireless NIC transceiver 120, a wireless NIC terminal 130, and a display device 140 located in a home 100.

The mobile terminal device 110 may be present in the home 100 and may be a laptop, a portable terminal, or a smart phone that may receive a wireless Ethernet signal. Hereinafter, in the present embodiment, it will be described on the assumption that the mobile terminal device 110 is a notebook.

The notebook 110 may wirelessly receive a gigabit-class wired Ethernet signal flowing into the home 100 from the external internet network 150 using the wireless NIC transceiver 120 and the wireless NIC terminal 130.

In addition, the notebook 110 may wirelessly transmit video and audio data to the wireless NIC terminal 130 through the wireless NIC transceiver 120. Then, the wireless NIC terminal 130 provides the received video and audio data to the display device 140 connected to the wireless NIC terminal 130 to play the video and audio data.

The wireless NIC transceiver 120 is connected to a PCI terminal or a PCI express terminal of the notebook 110. The wireless NIC transceiver 120 provides a wireless Ethernet signal received from the wireless NIC terminal 130 to the notebook 110. In addition, the wireless NIC transceiver 120 provides the wireless NIC terminal 130 with the video and audio data provided from the notebook 110.

The wireless NIC terminal 130 converts a gigabit-class wired Ethernet signal received from the external Internet network 150 into a wireless Ethernet signal and transmits the converted wireless Ethernet signal to the wireless NIC transceiver 120. In addition, the wireless NIC terminal 130 converts the image and audio data received from the wireless NIC transceiver 120 into a high-definition multimedia interface (HDMI) signal to display the display device ( 140).

The display device 140 may be present in the home 100 and may be a TV or a monitor capable of reproducing video and audio data. Hereinafter, in the present embodiment, it will be described on the assumption that the display device 140 is a TV.

The TV 140 may reproduce video and audio data provided from the wireless NIC terminal 130. That is, through the wireless NIC terminal 130, the TV 140 can play the video and audio data transmitted from the notebook 110 in real time.

Hereinafter, a wireless NIC transceiver and a wireless NIC terminal according to an embodiment of the present invention will be described in detail.

2 illustrates a configuration of a wireless NIC transceiver according to an embodiment of the present invention.

Referring to FIG. 2, the wireless NIC transceiver 120 includes a PCI connector 210, a wireless network processor 220, and an RF transceiver 230.

The PCI connector 210 is connected to a PCI terminal or a PCIe terminal, which is an external interface terminal of the notebook 110.

The PCI terminal is a local bus that directly connects the central processing unit (CPU) and peripheral devices of the notebook 110 to provide a data path for transferring data at high speed. In addition, the PCIe terminal was developed to overcome the shortcomings of the PCI terminal and uses a serial connection technology. For convenience of explanation, hereinafter, it will be assumed that the PCIe terminal is used in the present embodiment.

Through the PCIe terminal, the wireless NIC transceiver 120 may exchange data with the notebook 110 at high speed.

The wireless network processing unit 220 performs signal processing for transmitting data using WiGig, a next generation wireless transmission technology based on 60 GHz, or a broadband transmission technology defined in IEEE 802.15.c.

More specifically, the wireless network processing unit 220 encodes a PCIe signal input from the PCI connection unit 210 according to a predetermined coding scheme, modulates the encoded signal according to a predetermined modulation scheme, and outputs modulation symbols.

In this case, convolution coding, turbo coding, low density parity check coding, or the like may be used as the coding scheme. As the modulation scheme, m-PK (m-Phase Shift Keying) or m-Quardrature Amplitude Modulation (m-QAM) may be used.

The wireless network processing unit 220 adds a control signal such as a preamble signal to the modulation symbols and converts it into an analog signal. In addition, the wireless network processor 220 provides the converted analog signal to the RF transceiver 230.

In addition, the wireless network processor 220 converts an analog signal input from the RF transceiver 230 into a digital signal and then removes a control signal such as a preamble signal. Thereafter, the wireless network processor 220 demodulates the digital signal from which the control signal is removed according to a predetermined demodulation scheme, and then decodes the demodulated signal according to a predetermined decoding scheme to output a PCIe signal. The wireless network processing unit 220 provides the output PCIe signal to the PCI connection unit 210.

The RF transceiver 230 upwardly adjusts an analog signal input from the wireless network processor 220 to a frequency band signal (ie, 60 GHz band signal) to be transmitted, amplifies the upwardly adjusted RF signal through an antenna. send.

In addition, the RF transceiver 230 converts the RF signal received from the wireless NIC terminal 130 to a baseband signal, and provides the converted baseband signal to the wireless network processor 220.

As such, the wireless NIC transceiver 120 may transfer the Ethernet signal received from the wireless NIC terminal 130 to the notebook 110. In addition, the wireless NIC transceiver 120 may wirelessly transmit video and audio data received from the notebook 110 to the wireless NIC terminal 130.

On the other hand, the wireless NIC transceiver 120 is manufactured in the form of a PCIe card, it is coupled to the PCIe terminal configured on one side of the notebook (110). However, since the 60 GHz signal transmitted through the antenna of the wireless NIC transceiver 120 is very strong, it is difficult to insert the antenna portion into the notebook 110.

Therefore, the antenna portion of the wireless NIC transceiver 120 is located at the end of the PCIe card so as to be exposed to the outside of the notebook 110. In addition, a plurality of patch antennas may be used as the antenna of the wireless NIC transceiver 120.

3 shows a configuration of a wireless NIC terminal according to an embodiment of the present invention.

Referring to FIG. 3, the wireless NIC terminal 130 may include a NIC controller 310, a wireless network processor 320, an RF transceiver 330, a signal converter 340, a memory 350, and an HDMI connector 360. It includes.

The NIC controller 310 converts the gigabit-class wired Ethernet signal introduced into the home 100 from the external Internet network 150 into a PCIe signal, and transfers the converted PCIe signal to the wireless network processor 320.

The wireless network processing unit 320 performs signal processing for transmitting data using WiGig, a next generation wireless transmission technology based on 60 GHz, or a broadband transmission technology defined in IEEE 802.15.c.

More specifically, the wireless network processor 320 encodes the PCIe signal input from the NIC controller 310 according to a predetermined coding scheme, modulates the encoded signal according to a predetermined modulation scheme, and outputs modulation symbols.

Thereafter, the wireless network processing unit 320 adds a control signal such as a preamble signal to the modulation symbols and converts the signal into an analog signal. In addition, the wireless network processor 320 provides the converted analog signal to the RF transceiver 330.

In addition, the wireless network processor 320 converts an analog signal input from the RF transceiver 330 into a digital signal and then removes a control signal such as a preamble signal. Thereafter, the wireless network processor 320 demodulates the digital signal from which the control signal is removed according to a predetermined demodulation scheme, and then decodes the demodulated signal according to a predetermined decoding scheme to output a PCIe signal.

In addition, the wireless network processor 320 provides the output PCIe signal to the signal converter 340. In this case, the wireless network processing unit 320 may convert the PCIe signal into a universal serial bus (hereinafter referred to as "USB") signal and provide the signal to the signal conversion unit 340. In addition, the wireless network processor 320 may store the PCIe signal in the memory 350.

The RF transceiver 330 upwardly adjusts an analog signal input from the wireless network processing unit 320 to a frequency band signal (ie, 60 GHz band signal) to be transmitted, amplifies the upwardly adjusted RF signal through an antenna. send. In this case, the signal transmitted by the RF transceiver 330 is an Ethernet signal input from the external Internet network 150.

In addition, the RF transceiver 330 converts the RF signal received from the wireless NIC transceiver 120 to a baseband signal, and provides the converted baseband signal to the wireless network processor 320. In this case, the signal transmitted by the RF transceiver 330 is a video and audio data signal provided from the notebook 110.

The signal converter 340 converts the PCIe signal or the USB signal output from the wireless network processor 220 into an HDMI signal, and provides the converted HDMI signal to the HDMI connector 360. In addition, the signal converter 340 may store the HDMI signal in the memory 350.

The HDMI connector 360 is connected to the HDMI terminal of the TV 150 to transmit the HDMI signal input from the signal converter 340 to the TV 150.

The memory 350 may store video and audio data transmitted from the notebook 110. The memory 350 may include a disk, a magnetic disk, a mass storage medium such as a hard disk driver (HDD), a low-capacity storage medium such as a read-only memory (ROM) random access memory (RAM) memory, a memory, and / or the like. Other storage devices may be included.

As such, the wireless NIC terminal 130 may transmit the gigabit-class wired Ethernet signal received from the external internet network 150 to the notebook 110 using a wideband 60 GHz frequency band.

In addition, the wireless NIC terminal 130 may provide video and audio data wirelessly transmitted from the wireless NIC transceiver 120 to the TV 150. On the other hand, the wireless NIC terminal 130 may employ a plurality of patch antennas to improve the data rate.

As described above, the notebook user can use a high-speed data service by wirelessly accessing a gigabit-class wired Internet introduced into the home. In addition, the notebook user can wirelessly transmit the video and audio data stored in the notebook in real time to play through the TV.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

110: notebook 120: wireless NIC transceiver
130: wireless NIC terminal 140: display device
150: internet network

Claims (9)

A network interface card (NIC) controller for converting a gigabit wired Ethernet signal into a PCIe signal;
A first wireless network processing unit for converting the PCIe signal received from the NIC control unit into an analog signal, and
A wireless NIC terminal including a first RF transceiver configured to convert an analog signal input from the first wireless network processor into an RF signal of a 60 GHz frequency band and communicate with a wireless terminal device; And
An antenna and a second RF transceiver for transmitting and receiving an RF signal with the wireless NIC terminal, and
And a wireless NIC transceiver comprising a second wireless network processing unit converting the RF signal into a PCIe signal and providing a wireless Ethernet signal to the wireless terminal device.
The antenna is composed of a plurality of patch antenna, the network connection system exposed to the outside of the wireless terminal device. The method of claim 1,
The NIC control unit converts the wired Ethernet signal into a PCI signal. The method of claim 1,
The first RF transceiver transmits a video and audio data signal received from the wireless terminal device to a baseband signal,
And the first wireless network processing unit converts the converted baseband signal into a PCIe signal. The method of claim 3,
And a signal converter configured to convert the PCIe signal inputted from the first wireless network processor into an HDMI signal and provide the converted signal to a display device. 5. The method of claim 4,
And a memory for storing at least one of a PCIe signal input from the first wireless network processor and an HDMI signal input from the signal converter. The method of claim 1,
And the first wireless network processing unit performs signal processing using a WiGig transmission scheme. delete The method of claim 1,
The wireless NIC transceiver is provided with a PCI connection portion connected to the PCI terminal of the wireless terminal device. delete

Images